WO2011160472A1 - 传输间隙样式序列的处理方法、装置及系统 - Google Patents

传输间隙样式序列的处理方法、装置及系统 Download PDF

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Publication number
WO2011160472A1
WO2011160472A1 PCT/CN2011/071656 CN2011071656W WO2011160472A1 WO 2011160472 A1 WO2011160472 A1 WO 2011160472A1 CN 2011071656 W CN2011071656 W CN 2011071656W WO 2011160472 A1 WO2011160472 A1 WO 2011160472A1
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WO
WIPO (PCT)
Prior art keywords
transmission gap
gap pattern
pattern sequence
node
terminal
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PCT/CN2011/071656
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English (en)
French (fr)
Chinese (zh)
Inventor
柯雅珠
程翔
刘霖
Original Assignee
中兴通讯股份有限公司
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Application filed by 中兴通讯股份有限公司 filed Critical 中兴通讯股份有限公司
Priority to EP11797503.7A priority Critical patent/EP2587692A4/de
Priority to BR112012027998A priority patent/BR112012027998A2/pt
Priority to RU2012142266/07A priority patent/RU2561912C2/ru
Publication of WO2011160472A1 publication Critical patent/WO2011160472A1/zh

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Classifications

    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W24/00Supervisory, monitoring or testing arrangements
    • H04W24/10Scheduling measurement reports ; Arrangements for measurement reports
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04BTRANSMISSION
    • H04B7/00Radio transmission systems, i.e. using radiation field
    • H04B7/24Radio transmission systems, i.e. using radiation field for communication between two or more posts
    • H04B7/26Radio transmission systems, i.e. using radiation field for communication between two or more posts at least one of which is mobile
    • H04B7/2643Radio transmission systems, i.e. using radiation field for communication between two or more posts at least one of which is mobile using time-division multiple access [TDMA]
    • H04B7/2656Radio transmission systems, i.e. using radiation field for communication between two or more posts at least one of which is mobile using time-division multiple access [TDMA] for structure of frame, burst

Definitions

  • the present invention relates to the field of communications, and in particular to a method, an apparatus, and a system for processing a transmission gap pattern sequence.
  • GSM Global System Mobile
  • WCDMA Wideband Code Division Multiple Access
  • E-UTRA Enhanced Universal Radio Access
  • the second generation GSM system is mainly used for 7-carrier voice
  • the third generation WCDMA system is mainly used to carry packet domain services and session and video services, for the third generation.
  • the E-UTRA system focuses on seven-load ultra-high-speed packet domain services. Therefore, 40 pairs of existing network deployments, the mobility between systems of the second generation GSM system and the third generation WCDMA system are very important; and, in the near future, the third generation of E-UTRA The mobility management of the system, such as switching to the hotspot area of the E-UTRA system, will also become important.
  • inter-frequency handover based on load balancing between carrier frequencies of each layer is also necessary in the network of multi-carrier frequency networking.
  • the above-mentioned inter-system mobility management, as well as the load balancing between the carrier frequencies of each layer requires the measurement of the target system and the target carrier frequency in the prior handover preparation phase to accurately perform the handover decision.
  • the compression mode plays an important role in carrier frequency and intersystem measurement. When the compressed mode is used, the terminal will be able to measure the carrier frequency of the non-monthly service and the carrier frequency of other systems without configuring the dual receiver. When only one receiver terminal is configured, from the third-generation WCDMA system to the area covered by the second-generation GSM system, only the compressed mode can be used for inter-system measurement.
  • the compressed mode can also be used for terminal access to multiple carrier coverage areas of third-generation WCDMA systems.
  • the terminal can measure another non-monthly carrier frequency without losing any data transmitted on the monthly carrier frequency.
  • the compression mode is defined as a transmission mode in which data transmission is compressed in the time domain to produce a transmission gap.
  • the receiver of the terminal can use this transmission gap to tune to another carrier frequency for measurement.
  • the transmission gap is determined by the "transmission gap pattern sequence".
  • Each set of "transmission gap pattern sequences” is uniquely identified by “transmission gap pattern sequence identification” and can only be used for one type of “transmission gap pattern sequence measurement”, that is, “frequency division duplex measurement”I” time division duplex Measurement "I” GSM Carrier Received Signal Strength Indication Measurement” / "GSM Base Station Identification Color Code Initial Identification” I “GSM Base Station Identification Color Code Recognition Reconfirmation “I” Multiple Carrier Frequency Measurement "I”E- UTRA measurement” is one of the measurement uses for each measurement.
  • 1 is a schematic diagram of a "transmission gap pattern sequence” according to the related art, wherein each set
  • the "Transmission Gap Pattern Sequence” contains 2 alternate “Transport Gap Patterns 1" and “Transmission Gap Pattern 2". Each "transport gap pattern” provides one or two transmission gaps within a “transport gap pattern length”. In addition, each set of “transmission gap pattern sequences, including the transmission gap connection frame number (CFN) indicating the start/stop compression mode time, the number of repetitions of the transmission gap pattern, etc. These parameters are It is determined according to the "transmission gap pattern sequence measurement use". Considering that a large number of terminals appear in one cell, the available resources of this cell may not be sufficient to ensure the quality of all services of all terminals, resulting in congestion or overload.
  • CFN transmission gap connection frame number
  • the load balancing mechanism can be used, that is, the service is balanced to the lower load neighboring area.
  • This method can achieve the purpose of balancing the service to the lower load neighboring area at a lower cost.
  • load balancing needs to be performed between different nodes or between different systems, only the radio network controller can make a load balancing decision according to the load information of the cell, and prepare for inter-frequency handover or inter-system handover according to the decision.
  • the compression mode that must be initiated for inter-frequency measurement or inter-system measurement Considering the speeding up of the handover process, the reliability of the handover can be increased, especially in the area where the quality of the wireless signal deteriorates rapidly, and the risk of the user dropping the call can be reduced by speeding up the handover process.
  • the compression mode starts later, the compression mode continues. The shorter the time, the better, to improve the system capacity and user throughput. Therefore, the terminal can judge that the wireless signal quality of the current monthly service cell is not good, and apply to the node to start the compression mode to measure the inter-carrier/system-to-system neighbor. Zone, and the start/stop of the compression mode is controlled by the node ⁇ .
  • the node ⁇ when the node ⁇ decides to start/stop, the node ⁇ will start/stop the "transmission gap pattern sequence" to notify the terminal. Therefore, the quality of the wireless signal of the current monthly cell is not good between the terminal and the Node B, so that the compressed mode must be started for measurement.
  • the "transmission gap pattern sequence” is generated according to the "transmission gap pattern sequence,” and the “transmission gap pattern sequence” is stopped when the terminal and the node B stop the compression mode.
  • the above technique is applied in engineering, the following problems of compressed mode conflicts may occur.
  • the terminal Due to the poor quality of the wireless signal at which the terminal is located, the terminal has applied to the Node B to initiate a compressed mode to measure the neighboring cell between the carriers, and the Node B has controlled the terminal to initiate a compressed mode for the purpose of inter-carrier measurement.
  • the radio network controller also notifies the Node B to initiate a compression mode for inter-system measurement for load balancing execution. Therefore, Node B has a situation in which two sets of compression modes collide, which results in the terminal not being able to perform inter-carrier measurement or inter-system measurement based on the compressed mode, which ultimately causes the system load to be unreduced to affect the performance of the system equipment, and also causes The terminal did not switch in time to drop the call.
  • the present invention has been made in view of the problem of compression mode collision initiated by a node B in the related art. Therefore, it is a primary object of the present invention to provide a processing method, apparatus, and system for transmitting a gap pattern sequence to solve the above problems.
  • a processing method of a transmission gap pattern sequence is provided.
  • the processing method of the transmission gap pattern sequence according to the present invention includes: in a process in which the Node B and the terminal use the first transmission gap pattern sequence to generate a transmission gap, the Node B receives the indication from the radio network controller for indicating the second transmission.
  • the node B compares the priority of the first transmission gap pattern sequence with the priority of the second transmission gap pattern sequence; the node B and the terminal generate a transmission gap pattern sequence corresponding to the high priority indicated by the comparison result Transmission gap. If the comparison result indicates that the priority of the second transmission gap pattern sequence is higher than the priority of the first transmission gap pattern sequence; the transmission gap generated by the Node B and the terminal using the transmission gap pattern sequence corresponding to the compared high priority includes: Node B Sending a message for indicating that a transmission gap is generated by using the second transmission gap pattern sequence to the terminal; the Node B and the terminal stop using the first transmission gap pattern sequence to generate a transmission gap; and the Node B and the terminal use the second transmission gap pattern sequence to generate a transmission gap .
  • the method further includes: the Node B notifying the radio network controller Node B and the terminal to generate the transmission by using the second transmission gap pattern sequence.
  • the operation of the gap is started successfully. If the comparison result indicates that the priority of the first transmission gap pattern sequence is higher than the priority of the second transmission gap pattern sequence; the transmission gap generated by the Node B and the terminal using the transmission gap pattern sequence corresponding to the compared high priority includes: Node B The transmission gap is generated with the terminal continuing to use the first transmission gap pattern sequence.
  • the method further includes: the Node B notifying the radio network controller Node B and the terminal to generate the transmission by using the second transmission gap pattern sequence.
  • the operation of the gap failed to start.
  • the method further includes: before the node B and the terminal generate the transmission gap by using the first transmission gap pattern sequence, the method further includes: the node B, the terminal, and the radio network controller predetermining the priority of the first transmission gap pattern sequence and the second transmission gap pattern. The priority of the sequence.
  • the node B, the terminal, and the radio network controller predetermining the priority of the first transmission gap pattern sequence and the priority of the second transmission gap pattern sequence include: the radio network controller sends the first to the terminal by using radio resource control protocol layer control signaling a priority of the transmission gap pattern sequence and a priority of the second transmission gap pattern sequence; the radio network controller transmits the priority of the first transmission gap pattern sequence and the second transmission gap pattern sequence to the Node B through the NBAP protocol layer control signaling priority.
  • the method further includes: the Node B, the terminal, and the radio network controller predetermining a mode of the first transmission gap pattern sequence and a mode of the second transmission gap pattern sequence.
  • the node B, the terminal, and the radio network controller predetermining the mode of the first transmission gap pattern sequence and the mode of the second transmission gap pattern sequence include: the radio network controller sends the first transmission gap to the terminal by using radio resource control protocol layer control signaling a pattern of the pattern sequence and a pattern of the second transmission gap pattern sequence; the radio network controller transmits the pattern of the first transmission gap pattern sequence and the pattern of the second transmission gap pattern sequence to the Node B through the NBAP protocol layer control signaling.
  • the first transmission gap pattern sequence and the second transmission gap pattern sequence each include: a transmission gap pattern sequence identifier, a transmission gap pattern sequence measurement purpose, a first transmission gap pattern, and/or a second transmission gap pattern.
  • a node B includes: a first generation module configured to generate a transmission gap with a terminal using a first transmission gap pattern sequence; a first receiving module And being configured to receive a message from the radio network controller for indicating a second transmission gap pattern sequence; the comparing module is configured to compare the priority of the first transmission gap pattern sequence with the priority of the second transmission gap pattern sequence And a second generation module, configured to generate a transmission gap with a transmission gap pattern sequence corresponding to the high priority indicated by the terminal using the comparison result.
  • a terminal is provided.
  • the terminal according to the present invention includes: a third generation module configured to generate a transmission gap with the Node B using the first transmission gap pattern sequence; and a second receiving module configured to receive the sequence from the Node B for indicating the use of the second transmission gap pattern Generating a message for the transmission gap; a fourth generation module configured to generate a transmission gap with the Node B using the second transmission gap pattern sequence.
  • a processing system for transmitting a sequence of gap patterns is provided.
  • the processing system according to the transmission gap pattern sequence of the present invention includes the above-described Node B and the above-described terminal.
  • FIG. 1 is a schematic diagram of a "transmission gap pattern sequence" according to the related art
  • FIG. 3 is a flow chart showing the interaction of a process according to a preferred embodiment of the present invention
  • Figure 4 is a block diagram showing the structure of a process in accordance with a preferred embodiment of the present invention
  • Figure 5 is a block diagram showing the structure of a node B in accordance with an embodiment of the present invention
  • Figure 6 is a block diagram showing the structure of a terminal in the embodiment of the present invention.
  • FIG. 2 is a step S202 to a step S206.
  • Step S202 in the process that the Node B and the terminal generate a transmission gap by using the first transmission gap pattern sequence, the Node B receives a message from the radio network controller for indicating the second transmission gap pattern sequence.
  • Step S204 the Node B compares the priority of the first transmission gap pattern sequence with the priority of the second transmission gap pattern sequence.
  • Step S206 the node B generates a transmission gap with the transmission gap pattern sequence corresponding to the high priority indicated by the comparison result by the terminal.
  • the Node B selects a transmission gap pattern with a high priority to generate a transmission gap, thereby starting a compression mode based on the transmission gap pattern sequence, thereby avoiding a situation in which two sets of compression modes collide, thereby ensuring that the terminal performs compression-based Mode inter-carrier measurement or inter-system measurement, and guarantee the performance of the system equipment and the communication of the terminal.
  • the transmission gap generated by the Node B and the terminal using the transmission gap pattern sequence corresponding to the compared high priority includes: : Node B sends a message indicating that a transmission gap is generated using the second transmission gap pattern sequence to the terminal; the Node B and the terminal stop using the first transmission room The slot pattern sequence produces a transmission gap; the Node B and the terminal use the second transmission gap pattern sequence to generate a transmission gap.
  • the node B selects a high priority second transmission gap pattern sequence according to the priority order to replace the low priority first transmission gap pattern sequence to generate a transmission gap, thereby solving the problem occurring in the engineering application.
  • the defect of starting the compression mode conflict is simple and reliable.
  • the Node B after the Node B compares the priority of the first transmission gap pattern sequence with the priority of the second transmission gap pattern sequence, the Node B notifies the radio network controller Node B and the terminal to generate the transmission by using the second transmission gap pattern sequence. The operation of the gap is started successfully.
  • the Node B may respond to the radio network controller through the NBAP protocol layer control signaling and the compressed mode command response.
  • the Node B notifies the radio network controller that the set of "transmission gap pattern sequences that need to be initiated for this terminal has been successfully started.
  • This signaling carries the identity of the terminal and the transmission gap pattern sequence. Identifies the "," set of transmission gap pattern sequences, which have been successfully started.
  • the preferred embodiment can ensure that the radio network controller knows the state of the transmission gap between the Node B and the terminal.
  • the transmission gap generated by the Node B and the terminal using the transmission gap pattern sequence corresponding to the compared high priority includes: : Node B and the terminal continue to use the first transmission gap pattern sequence to generate a transmission gap.
  • the node B selects to use the high priority first transmission gap pattern sequence to generate a transmission gap according to the priority order, thereby solving the defect of the startup compression mode conflict occurring in the engineering application, and implementing the same.
  • the method is simple and reliable.
  • the Node B after the Node B compares the priority of the first transmission gap pattern sequence with the priority of the second transmission gap pattern sequence, the Node B notifies the radio network controller Node B and the terminal to generate a transmission gap by using the second transmission gap pattern sequence. The operation failed to start.
  • the Node B may respond to the radio network controller through the NBAP protocol layer control signaling and the compressed mode command response.
  • the Node B notifies the radio network controller that it is necessary to start the terminal to specify another "transmission gap pattern sequence, which has not been successfully started.
  • This signaling carries the identifier of the terminal and the transmission gap pattern sequence. Identifies the ",” set of transmission gap pattern sequences, information that was not successfully started, and, prohibits the wireless network controller The duration of the same content compression mode command is repeated again.
  • the radio network controller After receiving the compressed mode command response, the radio network controller knows that the "transmission gap pattern sequence" has not been successfully started, and repeatedly transmits the same content compression mode again in the forbidden radio network controller that starts timing from receiving the compressed mode command response. Within the duration of the command, the compressed mode command of the same content is no longer sent.
  • the preferred embodiment can ensure that the radio network controller knows the state of the transmission gap between the Node B and the terminal.
  • the Node B, the terminal, and the radio network controller predetermine the priority of the first transmission gap pattern sequence and the priority of the second transmission gap pattern sequence.
  • the priority of the transmission gap pattern sequence may be used to adjust the sequence of the transmission gap pattern sequence, so that the Node B determines whether to use the transmission gap pattern sequence to generate a transmission gap.
  • the node B, the terminal, and the radio network controller predetermine the priority of the first transmission gap pattern sequence and the priority of the second transmission gap pattern sequence, including: radio resource control (Radio Resource Control, referred to as RRC) protocol layer control signaling sends the priority of the first transmission gap pattern sequence and the priority of the second transmission gap pattern sequence to the terminal; the radio network controller passes the Node B Application Part (NBAP) protocol The layer control signaling sends the priority of the first transmission gap pattern sequence and the priority of the second transmission gap pattern sequence to the Node B.
  • RRC Radio Resource Control
  • NBAP Node B Application Part
  • the layer control signaling sends the priority of the first transmission gap pattern sequence and the priority of the second transmission gap pattern sequence to the Node B.
  • the priority of the first transmission gap pattern sequence and the priority of the second transmission gap pattern sequence are sent by the radio network controller, thereby implementing the Node B, the terminal, and the radio network controller.
  • the priority of the transmission gap pattern sequence is unified, and the implementation is simple.
  • the Node B, the terminal, and the radio network controller determine in advance a mode of the first transmission gap pattern sequence and a mode of the second transmission gap pattern sequence. It should be noted that the communication between the Node B, the terminal, and the radio network controller may capture the mode of the first transmission gap pattern sequence or the mode of the second transmission gap pattern sequence.
  • the Node B, the terminal, and the radio network controller decide to use the first transmission gap pattern sequence or the second transmission gap pattern sequence to generate a transmission gap, they only need to send a sequence for indicating the first transmission gap pattern or the second
  • the transmission gap pattern sequence generates a message for the transmission gap without having to transmit the first transmission
  • the mode of the gap pattern sequence or the pattern of the second transmission gap pattern sequence can reduce the transmission of information in the network and avoid format transmission errors of the transmission gap pattern sequence.
  • the node B, the terminal, and the radio network controller predetermine the mode of the first transmission gap pattern sequence and the mode of the second transmission gap pattern sequence: the radio network controller sends the first transmission to the terminal by using RRC protocol layer control signaling.
  • the radio network controller transmits the mode of the first transmission gap pattern sequence and the pattern of the second transmission gap pattern sequence to the Node B through the NBAP protocol layer control signaling.
  • the mode of the first transmission gap pattern sequence and the mode of the second transmission gap pattern sequence are sent by the radio network controller, thereby implementing transmission gap patterns in the Node B, the terminal, and the radio network controller.
  • the format of the sequence is unified and the implementation is simple.
  • the first transmission gap pattern sequence and the second transmission gap pattern sequence each include: a transmission gap pattern sequence identifier, a transmission gap pattern sequence measurement purpose, a first transmission gap pattern, and/or a second transmission gap pattern.
  • the transmission gap pattern sequence identifier, the transmission gap pattern sequence measurement purpose, the first transmission gap pattern, and/or the second transmission gap pattern are necessary for the Node B and the terminal to generate a transmission gap. Additionally, the first transmission gap pattern and/or the second transmission gap pattern may provide information of the transmission gap within one transmission gap pattern length.
  • the implementation process of the embodiment of the present invention will be described in detail below with reference to examples.
  • the High Speed Shared Control Channel (HS-SCCH) is a downlink control channel, which can be used to carry a High Speed Downlink Shared Channel (HS).
  • -DSCH Demodulate the information needed.
  • Node B can send high-speed shared control channel commands through HS-SCCH
  • the HS-SCCH order has 3 bits to indicate the type of high speed shared control channel command, with 3 bits for specific high speed shared control channel commands of this type.
  • the prior art only uses two types of high speed shared control channel commands of values 0 and 1.
  • the following embodiment will use the type of new high speed shared control channel command with a value of 2 to indicate the "boot" compression mode; the following embodiment will use a new type of high speed shared control channel command of value 3, To indicate "stop, compression mode; the following embodiment will use” with 3 bits to The 3 bits of the specific high-speed shared control channel command under this type, the following embodiment will use the values of these 3 bits from 1 to 7 to represent the "transmission gap pattern sequence identifier", respectively. Identifying a "transmission gap pattern sequence”.
  • Preferred Embodiment 1 This preferred embodiment describes a process of generating a transmission gap in a description of a transmission gap pattern sequence identified by a terminal and a Node B in accordance with a high priority transmission gap pattern sequence identifier 1.
  • the node B receives the transmission gap pattern sequence identified by the low priority transmission gap pattern sequence identifier 6 sent by the radio network controller, and the terminal and the node B continue to follow the high priority transmission gap pattern sequence identifier 1
  • the description of the transmission gap pattern sequence is used to generate a transmission gap.
  • Figure 3 is an interaction flow diagram of a processing procedure according to a preferred embodiment of the present invention, including the following steps S302 to S312.
  • Step S302 Terminal and Node B, wireless network
  • the controller pre-agreed the "transmission gap pattern sequence" information for starting the compression mode and the priority letter for each set of transmission gap pattern sequences.
  • the radio network controller configures, by the RRC protocol layer control signaling, the "transmission gap pattern sequence, the information and the priority information of each transmission gap pattern sequence in the compressed mode, and the radio network controller through the NBAP.
  • the protocol layer control signaling is configured to the Node B to configure the "transmission gap pattern sequence, the information and the priority information of each transmission gap pattern sequence.”
  • the information of the "transmission gap pattern sequence" for starting the compression mode includes: “Transmission gap pattern sequence", for measurement purposes of "frequency division duplex measurement", "transmission gap pattern sequence identification" is 1.
  • This set of “transmission gap pattern sequence” contains 2 alternate “transmission gap patterns ⁇ and" Transmission gap pattern 2". Each "transport gap pattern” provides a transmission gap within a “transport gap pattern length”.
  • the second set of “transmission gap pattern sequence” is used for the measurement purpose of "GSM base station identification color code initial recognition", and the "transmission gap pattern sequence identifier" is 6.
  • This set of “Transmission Gap Pattern Sequence” contains 2 alternate “Transport Gap Pattern 1" and “Transmission Gap Pattern 2", and each "Transport Gap Pattern” provides two transmission gaps within one "Transport Gap Pattern Length".
  • the priority information of each transmission gap pattern sequence specifically includes: The first set of "transmission gap pattern sequences" with a "transmission gap pattern sequence identifier" of 1 has a priority of 1 (higher priority);
  • the "Transmission Gap Pattern Sequence Identifier”, the second set of “Transmission Gap Pattern Sequences” of 6, has a priority of 6 (lower priority).
  • the "transmission gap pattern sequence identifier”, the first set of “transmission gap pattern sequence” of 1, has a higher priority than the second set of “transmission gap pattern sequence identifier” of "transmission gap pattern sequence”, step S304:
  • the terminal and the Node B have generated a transmission gap in accordance with the description of the "transmission gap pattern sequence" identified by the "transmission gap pattern sequence identifier" 1.
  • Step S306 The Node B receives the NBAP protocol layer control signaling sent by the radio network controller, and compresses the mode command.
  • Step S308 Node B compares the set of "transmission gap pattern sequences" identified by the "transmission gap pattern sequence identifier” 1 that has been currently activated, and the "transmission gap pattern sequence identifier" that the radio network controller needs to specify for the terminal to start.
  • Step S310 The Node B responds to the radio network controller by using the NBAP protocol layer control signaling, and compresses the mode command response. Through this signaling, the Node B notifies the radio. The network controller needs to start the specified "transmission gap pattern sequence identifier" for this terminal, and the "transmission gap pattern sequence” identified by 6 is not successfully started.
  • the signaling carries the identifier of the terminal, "transmission gap pattern sequence identifier, which is 6, the set of transmission gap pattern sequences, information that has not been successfully started, and prohibits the radio network controller from repeatedly transmitting the same content compression again.
  • the mode command has a duration of 2 seconds. After receiving the compressed mode command response, the radio network controller knows that the "transmission gap pattern sequence" has not been successfully started, and does not send the same content within the length of 2 seconds from the receipt of the compressed mode command response. Compress mode command.
  • Step S312 The terminal and the Node B continue to generate a transmission gap according to the description of the "transmission gap pattern sequence" identified by the "transmission gap pattern sequence identifier" 1.
  • the node B when the node B receives the low-priority transmission gap pattern sequence from the radio network controller, the high-priority transmission gap pattern sequence that continues to be used generates a transmission gap, and the correlation is solved.
  • the problem of compression mode conflict initiated by the node B in the technology ensures that the terminal performs inter-carrier measurement or inter-system measurement based on the compressed mode, and ensures the performance of the system device and the communication of the terminal, and the implementation manner is simple and reliable.
  • Preferred Embodiment 2 This preferred embodiment 2 describes that in the process of generating a transmission gap by the terminal and the Node B according to the description of the transmission gap pattern sequence identified by the low priority transmission gap pattern sequence identifier 6, the Node B receives the wireless network.
  • the transmission gap pattern sequence identified by the high priority transmission gap pattern sequence identifier 1 issued by the controller, the terminal and the node B are replaced by the description of the transmission gap pattern sequence identified by the high priority transmission gap pattern sequence identifier 1
  • the low priority transmission gap pattern sequence identifies the description of the transmission gap pattern sequence identified by 6 to produce a transmission gap.
  • 4 is an interaction flowchart of a processing procedure according to a preferred embodiment 2 of the present invention, including the following steps S402 to 4: S414.
  • the radio network controller configures, by the RRC protocol layer control signaling, the "transmission gap pattern sequence, the information, and the priority information of each set of transmission gap pattern sequences in the compressed mode, and the radio network controller through the NBAP protocol layer.
  • the control signaling configures the Node B with a "transmission gap pattern sequence, information, and priority information for each set of transmission gap pattern sequences that initiate compression mode.
  • the "transmission gap pattern sequence” information for starting the compression mode specifically includes: The first set of "transmission gap pattern sequence" for the measurement purpose of "frequency division duplex measurement", "transmission gap pattern sequence identifier" is 1. This set of "Transmission Gap Pattern Sequence" contains 2 alternate “Transport Gap Patterns" and "Transmission Gap Patterns 2".
  • Each "Transport Gap Pattern” provides a transmission gap within a “Transmission Gap Pattern Length”.
  • "Transmission gap pattern sequence” used for measurement purposes of "GSM base station identification color code initial recognition", "Transmission gap pattern sequence identifier" is 6. This set of “transmission gap pattern sequence” contains 2 alternate “transmission gap patterns 1 "and” transmission gap pattern 2", and each "transport gap pattern” provides two transmission gaps within one "transport gap pattern length”.
  • the priority information of each transmission gap pattern sequence specifically includes:
  • the first set of "Transmission Gap Pattern Sequences" with a “Transmission Gap Pattern Sequence Identifier” of 1 has a priority of 1 (higher priority);
  • the "Transmission Gap Pattern Sequence Identifier" the second set of “Transmission Gap Pattern Sequences” of 6, has a priority of 6 (lower priority).
  • Step S404 The terminal and the node B have generated the transmission gap according to the description of the set of "transmission gap pattern sequences" identified by the "transmission gap pattern sequence identifier” 6.
  • Step S406 The node B receives the NBAP protocol from the radio network controller. Layer Control Signaling, Compressed Mode Command. Through this signaling, the radio network controller informs the Node B that it needs to start the set of "Transmission Gap Pattern Sequence” specified by the "Transmission Gap Pattern Sequence Identifier" for this terminal.
  • Step S408 Node B compares the currently transmitted "transmission gap pattern sequence identifier, 6 identifiers The "transmission gap pattern sequence" and the radio network controller need to initiate the terminal to specify the "transmission gap pattern sequence identifier" as the priority of the "transmission gap pattern sequence” identified by 1, and the node B is prioritized. Sorting to select the high-priority "transmission gap pattern sequence,", Node B finally decides to execute the transmission gap pattern sequence as "transmission gap” The pattern sequence identifies the set of "transmission gap pattern sequences" identified by 1.
  • Step S410 Node B transmits "HS-SCCH order" through the HS-SCCH physical channel to initiate the action and start of the compressed mode.
  • the "transmission gap pattern sequence identifier,” is notified to the terminal.
  • the action of starting the compressed mode is represented by using a type of a new high speed shared control channel command with a value of 2;
  • the initiated "transmission gap pattern sequence” is identified by “transmission gap pattern sequence identification” 1 , "
  • the transmission gap pattern sequence identification "1” is represented by the value of "1" of the specific high-speed shared control channel command having "3 bits for a specific high-speed shared control channel command under this type".
  • Step S412 The Node B responds to the radio network controller by using the NBAP protocol layer control signaling and compressing the mode command response. Through this signaling, Node B informs the radio network controller that it needs to The "Transmission Gap Pattern Sequence” identified by the "Transport Gap Pattern Sequence Identifier" specified by the terminal for booting has been successfully started.
  • the signaling carries the identifier of the terminal, and the "transmission gap pattern sequence identifier" is 1, and the set of "transmission gap pattern sequence” has been successfully started.
  • Step S414 The terminal and the node B interrupt the set of "transmission gap pattern sequences" identified by the "transmission gap pattern sequence identifier", and according to the "transmission gap pattern sequence identifier", the "transmission gap pattern sequence” identified by 1 Description to generate a transmission gap.
  • the node B and the terminal use the high-priority transmission gap pattern sequence received from the radio network controller to generate a transmission gap instead of the low-priority transmission gap pattern sequence being used.
  • the problem of the compression mode conflict initiated by the node B in the related art is solved, and the terminal is guaranteed to perform inter-carrier measurement or inter-system measurement based on the compressed mode, and the performance of the system device and the communication of the terminal are ensured.
  • FIG. 5 is a structural block diagram of a Node B, including a first generation module 52, a first receiving module 54, a comparison module 56, and a second generation module 58, in accordance with an embodiment of the present invention. The structure is described in detail below.
  • the first generating module 52 is configured to generate a transmission gap with the terminal using the first transmission gap pattern sequence;
  • the first receiving module 54 is configured to receive a message from the radio network controller for indicating the second transmission gap pattern sequence; 56, connected to the first generating module 52 and the first receiving module 54, configured to compare the priority of the first transmission gap pattern sequence used by the first generating module 52 with the second transmission gap pattern sequence received by the first receiving module 54
  • the second generation module 58 is connected to the comparison module 56, and is configured to generate a transmission gap with a transmission gap pattern sequence corresponding to the high priority indicated by the comparison result of the terminal using the comparison module 56.
  • the Node B comparison module 56 compares the priorities, and selects a transmission gap pattern with a high priority to generate a transmission gap, thereby starting a compression mode based on the transmission gap pattern sequence. It is possible to avoid a situation in which two sets of compression modes collide, thereby ensuring that the terminal performs inter-carrier measurement or inter-system measurement based on the compressed mode, and ensures the performance of the system device and the communication of the terminal.
  • FIG. 6 is a structural block diagram of a terminal, including a third generating module 62, a second receiving module 64, and a fourth generating module 66, according to an embodiment of the present invention. The structure is described in detail below.
  • a third generation module 62 configured to generate a transmission gap with the Node B using the first transmission gap pattern sequence
  • the second receiving module 64 is configured to receive a message from the Node B indicating that the transmission gap is generated using the second transmission gap pattern sequence
  • the fourth generating module 66 is connected to the third generating module 62 and the second receiving module 64, and is arranged to replace the first used by the third generating module 62 with the second transmission gap pattern sequence received by the node B using the second receiving module 64.
  • the transmission gap pattern sequence produces a transmission gap.
  • a processing system for transmitting a sequence of gap patterns which system can be used to implement the processing method of the above-described transmission gap pattern sequence.
  • the system includes the above-mentioned node B including a first generating module 52, a first receiving module 54, a comparing module 56 and a second generating module 58, and further comprising the third generating module 62, the second receiving module 64 and the fourth generating module. 66 terminal.
  • the processing system of the node B, the terminal, and the foregoing transmission gap pattern sequence described in the foregoing device embodiment corresponds to the foregoing method embodiment, and the specific implementation process has been described in detail in the method embodiment. This is no longer a comment.
  • a processing method, apparatus and system for transmitting a gap pattern sequence are provided.
  • the transmission gap is generated by using a high-priority transmission gap pattern sequence, which solves the problem of the compression mode conflict initiated by the node B in the related art, and ensures that the terminal performs inter-carrier measurement or inter-system measurement based on the compression mode, and Ensure the performance of the system equipment and the communication of the terminal.
  • a high-priority transmission gap pattern sequence which solves the problem of the compression mode conflict initiated by the node B in the related art, and ensures that the terminal performs inter-carrier measurement or inter-system measurement based on the compression mode, and Ensure the performance of the system equipment and the communication of the terminal.
  • the invention is not limited to any specific combination of hardware and software.
  • the above is only the preferred embodiment of the present invention, and is not intended to limit the present invention, and various modifications and changes can be made to the present invention. Any modifications, equivalent substitutions, improvements, etc. made within the scope of the present invention are intended to be included within the scope of the present invention.

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  • Engineering & Computer Science (AREA)
  • Computer Networks & Wireless Communication (AREA)
  • Signal Processing (AREA)
  • Mobile Radio Communication Systems (AREA)
  • Small-Scale Networks (AREA)
  • Communication Control (AREA)
PCT/CN2011/071656 2010-06-22 2011-03-09 传输间隙样式序列的处理方法、装置及系统 WO2011160472A1 (zh)

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EP11797503.7A EP2587692A4 (de) 2010-06-22 2011-03-09 Verfahren, vorrichtung und system zur verarbeitung der übertragungslücken-mustersequenz
BR112012027998A BR112012027998A2 (pt) 2010-06-22 2011-03-09 método para processamento de uma sequência padrão de lacuna de transmissão, nodo b, terminal e sistema para processamento de uma sequência padrão de lacuna de transmissão
RU2012142266/07A RU2561912C2 (ru) 2010-06-22 2011-03-09 Способ, устройство и система для формирования последовательности серий временных интервалов передачи данных

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CN102300233B (zh) 2015-08-12
CN102300233A (zh) 2011-12-28
EP2587692A4 (de) 2016-02-17

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